Formation of stable submicron peptide or protein particles by thin film freezing

ABSTRACT

The present invention includes compositions and methods for preparing micron-sized or submicron-sized particles by dissolving a water soluble effective ingredient in one or more solvents; spraying or dripping droplets solvent such that the effective ingredient is exposed to a vapor-liquid interface of less than 50, 100, 150, 200, 250, 200, 400 or 500 cm −1  area/volume to, e.g., increase protein stability; and contacting the droplet with a freezing surface that has a temperature differential of at least 30° C. between the droplet and the surface, wherein the surface freezes the droplet into a thin film with a thickness of less than 500 micrometers and a surface area to volume between 25 to 500 cm −1 .

TECHNICAL FIELD OF THE INVENTION

The present invention relates in general to the field of particle formation, and more particularly, to the formation of stable submicron protein particles.

BACKGROUND OF THE INVENTION

Without limiting the scope of the invention, its background is described in connection with methods to produce stable submicron peptide and protein particles.

For example, the U.S. Pat. No. 6,723,347 teaches a process for producing protein powder. The '347 patent describes a process for conveniently producing a stable protein powder retaining the higher-order structure at a high level which comprises freezing a protein-containing solution at a cooling rate of about −300 to −10° C./min. and then drying.

Another example can be found in U.S. Pat. No. 6,284,282, in which Maa et al. teach a method of spray freeze drying proteins for pharmaceutical administration. Maa's application relates to the spray freeze dry preparation of dry powder formulations of therapeutic proteins suitable for administration via pulmonary delivery.

Yet another example is found in U.S. Pat. No. 6,862,890 entitled “Process for Production of Nanoparticles and Microparticles by Spray Freezing into Liquid”. The '890 patent provides a system and a method for the production of microparticles and nanoparticles of materials that can be dissolved. The system and method provide quicker freezing times, which in turn produces a more uniform distribution of particle sizes, smaller particles, particles with increased porosity and a more intimate mixing of the particle components. The system and method of the '890 patent also produce particles with greater surface area than conventional methods, and a method for the preparation of particles. An effective ingredient is mixed with water, one or more solvents, or a combination thereof, and the resulting mixture is sprayed through an insulating nozzle located at or below the level of a cryogenic liquid. The spray generates frozen particles.

Yet another example is shown in the U.S. Pat. No. 6,254,854 by Edwards et al. entitled “Porous particles for deep lung delivery”. The '854 patent teaches improved porous particles for drug delivery to the pulmonary system, and methods for their synthesis and administration. The porous particles are made of a biodegradable material and have a mass density less than 0.4 g/cm³. The particles may be formed of biodegradable materials such as biodegradable polymers. For example, the particles may be formed of a functionalized polyester graft copolymer consisting of a linear a hydroxy-acid polyester backbone having at least one amino acid group incorporated therein and at least one poly(amino acid) side chain extending from an amino acid group in the polyester backbone. Porous particles having a relatively large mean diameter, for example greater than 5 μm, can be used for enhanced delivery of a therapeutic agent to the alveolar region of the lung. The porous particles incorporating a therapeutic agent may be effectively aerosolized for administration to the respiratory tract to permit systemic or local delivery of wide variety of therapeutic agents.

Finally, U.S. Pat. No. 5,019,400 teaches a very low temperature casting of controlled release microspheres The '400 patent describes a process for preparing microspheres using very cold temperatures to freeze polymer-biologically active agent mixtures into polymeric microspheres with very high retention of biological activity and material. Polymer is dissolved in a solvent together with an active agent that can be either dissolved in the solvent or dispersed in the solvent in the form of microparticles. The polymer/active agent mixture is atomized into a vessel containing a liquid non-solvent, alone or frozen and overlayed with a liquified gas, at a temperature below the freezing point of the polymer/active agent solution. The cold liquified gas or liquid immediately freezes the polymer droplets. As the droplets and non-solvent for the polymer is warmed, the solvent in the droplets thaws and is extracted into the non-solvent, resulting in hardened microspheres.

A disadvantage of the above mentioned techniques when used with proteins and peptides is that it that proteins and peptides often form aggregates when the particle size becomes smaller than about 1 μm, because they are exposed to large vapor-liquid interfaces during water removal. These aggregates remain upon reconstitution in buffer. Therefore, such techniques may not lead to biologically active micronized protein powders.

Furthermore, it is difficult to control the particle size distribution in these processes in many cases. Methods are needed to remove water from solutions of peptides and proteins to produce small particles, with control of the size distribution, without forming protein aggregates.

SUMMARY OF THE INVENTION

The present inventors realized a need for a simple, efficient and robust process for freezing either small (<1 mL) quantities of protein solution or commercial quantities, that can produce stable submicron particles, e.g., protein particles.

More particularly, the present invention includes compositions and method for preparing micron-sized or submicron-sized particles by dissolving a water soluble effective ingredient in one or more solvents; spraying or dripping droplets solvent such that the effective ingredient is exposed to an vapor-liquid interface of less than 50, 100, 150, 200, 250, 300, 400 or even 500 cm⁻¹ area/volume; and contacting the droplet with a freezing surface that has a temperature differential of at least 30° C. between the droplet and the surface, wherein the surface freezes the droplet into a thin film with a thickness of less than 500 micrometers and a surface area to volume between 25 to 500 cm⁻¹. In one aspect, the method further includes the step of removing the solvent from the frozen material to form particles. In one aspect, the droplets freeze upon contact with the surface in about 50, 75, 100, 125, 150, 175, 200, 250, 500, 1,000 and 2,000 milliseconds. In another aspect, the droplets freeze upon contact with the surface in about 50 and 150 milliseconds. In another aspect, the droplet has a diameter between 2 and 5 mm at room temperature. In another aspect, the droplet forms a thin film on the surface of between 50 and 500 micrometers in thickness. In another aspect, the droplets have a cooling rate of between 50-250 K/s. In another aspect, the particles after solvent removal have a surface area of 10, 15, 25, 50, 75, 100, 125, 150 or 200 m²/gr.

In one embodiment, the effective ingredient is a protein or peptide and the particle has less than 50% of the peptide or peptide or protein at the particle surface. The effective ingredient or active agent may a protein or peptide and the particle has less than 25, 15, 10 or 5% of the peptide or peptide or protein at the surface. In another aspect, the particles are submicron in diameter and may even include particle fibers less than one micron in diameter. In another aspect, the effective ingredient includes a surfactant peptide or peptide or protein, a DNase, and α-1-antitrypsin, an interleukin, a protease inhibitor, an interleukin receptor, a monoclonal antibody, a muramyl dipeptide, a catalase, a phosphatase, a kinase, a receptor antagonist, a receptor agonist, a dismutase, a calcitonin, a hormone, an interfereon, insulin, a growth factor, erythropoietin, heparin, vasopressin, peptides, albuterol sulfate, terbutaline sulfate; insulin, glucagon-like peptide, C-Peptide, erythropoietin, calcitonin, human growth hormone, leutenizing hormone, prolactin, adrenocorticotropic hormone, leuprolide, interferon α-2b, interferon beta-1a, sargramostim, aldesleukin, interferon α-2a, interferon alpha, n3 α,-peptide or proteinase inhibitor; etidronate, nafarelin, chorionic gonadotropin, prostaglandin E2, epoprostenol, acarbose, metformin, or desmopressin, cyclodextrin, antibiotics; and the pharmacologically acceptable organic and inorganic salts or metal complex thereof.

In one embodiment, the surface is cooled by a cryogenic solid, a cryogenic gas, a cryogenic liquid or a heat transfer fluid capable of reaching cryogenic temperatures or temperatures below the freezing point of the solvent. In another aspect, the solvent further includes one or more excipients selected from sugars, phospholipids, surfactants, polymeric surfactants, vesicles, polymers, including copolymers and homopolymers and biopolymers, dispersion aids, and serum albumin. In another aspect, the effective ingredient includes an enzyme and the enzymatic activity of the enzyme is greater than 90%. In another aspect, the effective ingredient includes a peptide or protein and peptide or protein aggregation is less than 3%. In another aspect, the temperature differential between the droplet and the surface is at least 50° C.

The present invention also includes a pharmaceutical formulation that includes drug particles prepared by preparing micron-sized or submicron-sized particles by dissolving a water soluble effective ingredient or active agent in one or more solvents; spraying or dripping droplets solvent such that the effective ingredient is exposed to an vapor-liquid interface of less than 50 cm⁻¹ area/volume; and contacting the droplet with a freezing surface that has a temperature differential of at least 30° C. between the droplet and the surface, wherein the surface freezes the droplet into a thin film with a thickness of less than 500 micrometers and a surface area to volume between 25 to 500 cm⁻¹.

Another embodiment of the present invention includes a method for preparing micron-sized or submicron-sized solvent particles including: spraying or dripping droplets of a water soluble peptide or protein in a solvent, wherein the droplet is exposed to an vapor-liquid interface of less than 50 cm⁻¹ area/volume; contacting the droplet with a freezing surface that has a temperature differential of at least 30° C. between the droplet and the surface, wherein the droplet freezes into a thin film with a thickness of less than 500 micrometers and a surface area to volume between 25 to 500 cm⁻¹. The method may further include the step of removing the solvent from the frozen material to form particles. In another aspect, the solvent further includes at least one or more excipient or stabilizers selected from, e.g., sugars, phospholipids, surfactants, polymeric surfactants, vesicles, polymers, including copolymers and homopolymers and biopolymers, dispersion aids, and serum albumin. In another aspect, the peptide or protein includes an enzyme and the enzymatic activity of the enzyme is greater than 90%. In another aspect, the peptide or protein aggregation is less than 3%. In another aspect, the temperature differential between the solvent and the surface is at least 50° C. In another aspect, the particle has less than 50% of the peptide or protein at the surface. In another aspect, the particle has less than 25, 15, 10 or 5% of the peptide or protein at the surface. In another aspect, the peptide or protein includes, e.g., a surfactant peptide or protein, DNase, and α-1-antitrypsin, interleukin, interferon, protease inhibitor, interleukin receptor, monoclonal antibody, muramyl dipeptide, catalase, phosphatase, kinase, receptor antagonist, receptor agonist, dismutase, calcitonin, hormone, insulin, a growth factor, erythropoietin, heparin, vasopressin, peptides, glucagon-like peptide, C-Peptide, erythropoietin, human growth hormone, luteinizing hormone, prolactin, adrenocorticotropic hormone, leuprolide, interferon, interferon α-2b, interferon beta-1a, sargramostim, aldesleukin, interferon α-2a, interferon alpha, n3 α,-peptide or proteinase inhibitor; and the pharmacologically acceptable organic and inorganic salts or metal complex thereof.

In one embodiment, the present invention includes a formulation, e.g., a pharmaceutical formulation or active agent, that includes drug particles prepared by preparing micron-sized or submicron-sized solvent particles including: spraying or dripping droplets of a water soluble peptide or protein in a solvent, wherein the droplet is exposed to an vapor-liquid interface of less than 50 cm⁻¹ area/volume; contacting the droplet with a freezing surface that has a temperature differential of at least 30° C. between the droplet and the surface, wherein the droplet freezes into a thin film with a thickness of less than 500 micrometers and a surface area to volume between 25 to 500 cm⁻¹.

Yet another embodiment includes compositions and methods for preparing micron-sized or submicron-sized particles by preparing an emulsion including a water soluble effective ingredient in solution; spraying or dripping droplets of the solution such that the effective ingredient is exposed to an vapor-liquid interface of less than 50 cm⁻¹ area/volume; and contacting the droplet with a freezing surface that has a temperature differential of at least 30° C. between the droplet and the surface, wherein the surface freezes the droplet into a thin film with a thickness of less than 500 micrometers and a surface area to volume between 25 to 500 cm⁻¹.

Yet another embodiment includes a system for preparing solvent nano and micro-particles that includes a solvent source composed of one or more solvents; a vessel containing a cryogenic liquid selected from cryogenic liquid selected from the group consisting of carbon dioxide, nitrogen, ethane, propane, helium, argon, or isopentane; and an insulating nozzle having an end and a tip, wherein the end of the nozzle is connected to the solvent source and the tip is placed above, at or below the level of the cryogenic liquid. In one aspect, the solution source further includes water, at least one organic solvent, or a combination thereof. In one aspect, the organic solvent is elected from the group consisting of ethanol, methanol, tetrahydrofuran, acetonitril acetone, tert-butyl alcohol, dimethyl sulfoxide, N,N-dimethyl formamide, diethyl ether, methylene chloride, ethyl acetate, isopropyl acetate, butyl acetate, propyl acetate, toluene, hexanes, heptane, pentane, and combinations thereof.

In another embodiment, a method for spray freezing including: spraying a solvent through an insulating nozzle located above, at or below the level of a cryogenic liquid, wherein the spray rapidly generates frozen solvent particles having a size range of 10 nm to 10 microns. In one aspect, the solvent particles produced have a particle size of less than 10 microns. In another aspect, the solvent particle has a surface area greater than 50 m²/g. In one aspect, the cryogenic material is a liquid, a gas, a solid or a surface. In another aspect, the one or more solvents comprises a first solvent that is less volatile than a second solvent, wherein the more volatile solvent is removed but not the second solvent. In yet another aspect, the one or more solvents comprises a first solvent that is less volatile than a second solvent, wherein the more volatile solvent is removed by evaporation, lyophilization, vacuum, heat or chemically.

Yet another embodiment of the present invention includes a single-step, single-vial method for preparing micron-sized or submicron-sized particles by reducing the temperature of a vial wherein the vial has a temperature differential of at least 30° C. between the solvent and the vial and spraying or dripping solvent droplets of a water soluble effective ingredient dissolved in one or more solvents directly into the vial such that the effective ingredient is exposed to a vapor-liquid interface of less than 500 cm⁻¹ area/volume, wherein the surface freezes the droplet into a thin film with a thickness of less than 500 micrometers and a surface area to volume between 25 to 500 cm⁻¹. The droplets freeze may upon contact with the surface in about 50, 75, 100, 125, 150, 175, 200, 250, 500, 1,000 and 2,000 milliseconds, and may even freeze upon contact with the surface in about 50, 150 to 500 milliseconds. In one example, a droplet has a diameter between 0.1 and 5 mm at room temperature or even a diameter between 2 and 4 mm at room temperature. In another example, the droplet forms a thin film on the surface of between 50 and 500 micrometers in thickness. In one specific example the droplets will have a cooling rate of between 50-250 K/s. The vial may be cooled by a cryogenic solid, a cryogenic gas, a cryogenic liquid, a freezing fluid, a freezing gas, a freezing solid, a heat exchanger, or a heat transfer fluid capable of reaching cryogenic temperatures or temperatures below the freezing point of the solvent. The vial may even be rotated as the spraying or droplets are delivered to permit the layering or one or more layers of the final particles. In one example, the vial, the water soluble effective ingredient and the one or more solvents are pre-sterilized prior to spraying or dripping. The method may also include the step of spraying or dripping is repeated to overlay one or more thin films on top of each other to fill the vial to any desired level up to totally full.

BRIEF DESCRIPTION OF THE DRAWINGS

For a more complete understanding of the features and advantages of the present invention, reference is now made to the detailed description of the invention along with the accompanying figures and in which:

FIG. 1A is a diagram of the thin film freezing process displaying the falling droplet.

FIG. 1B is a diagram of falling droplet spreading after impact on the stainless steel surface.

FIG. 1C is a diagram of a droplet during cooling and freezing as a thin film.

FIGS. 2A and 2B are infrared (IR) photographs of an aqueous droplet impinging and freezing on a stainless steel surface at 223 K and at 133K, respectively.

FIG. 3 is a plot of IR intensity versus time for an aqueous thin film on stainless steel surface at 223 K.

FIG. 4 is a plot of laser light scattering of particles formed by thin film freezing.

FIGS. 5A and 5B are scanning electron micrograph (SEM) images of particles from 5 mg/mL lysozyme solutions processed by thin film freezing at surface temperatures of 223 K, and 133K, respectively.

FIG. 5C is a scanning electron micrograph (SEM) of particles from 5 mg/mL lysozyme solutions using spray freezing into liquid with liquid nitrogen.

FIG. 6A to 6C are SEM images of particles from 50 mg/mL lysozyme solution processed by thin film freezing, by spray freezing into liquid nitrogen, and by spray freeze-drying-10 μm into liquid nitrogen, respectively.

FIG. 7A is a graph of temperature versus depth profiles of thin aqueous films cooled on a surface at 223 K for a 220 μm thin film.

FIG. 7B is a graph of temperature versus depth profiles of thin aqueous films cooled on a surface at 133 K for a 320 μm thin film.

FIG. 8A is a picture of nucleation and growth of protein particle in unfrozen channels between glassy frozen water domains with high supercooling in the thin film freezing, spray freezing into liquid, and spray freeze-drying processes.

FIG. 8B is a picture of nucleation and growth of protein particle in unfrozen channels between glassy frozen water domains with low supercooling in shelf lyophilization.

FIG. 9 is a graph of freezing time versus exposure to gas-liquid interface for lyophilization, thin film freezing (TFF), spray freezing into liquid (SFL), and spray freeze-drying (SFD).

FIG. 10A is a SEM image of top of dried lysozyme thin film at the center.

FIG. 10B is a SEM image of top of dried lysozyme thin film at approximately 10 μm from the edge.

FIG. 11 is a graph that shows thin film freezing of lysozyme with various amounts of Ethanol in original Concentration Measured after 10 minutes of sonication by Malvern Mastersizer.

FIG. 12 is a graph that shows various high initial solubilized concentrations of lysozyme frozen by TFF and then lyophilized.

FIGS. 13A and 13B shows the morphologies of TFF lysozyme prepared in glass vial (TFF lys: feed=5 mg/mL prepared directly in a glass vial) versus a TFF lysozyme prepared on a drum (FIGS. 13C to 13D)(TFF lys: feed=5 mg/mL prepared on TFF drum).

FIG. 14 shows the resuspended suspension of TFF particles in a suitable solvent for parenteral delivery.

DETAILED DESCRIPTION OF THE INVENTION

While the making and using of various embodiments of the present invention are discussed in detail below, it should be appreciated that the present invention provides many applicable inventive concepts that can be embodied in a wide variety of specific contexts. The specific embodiments discussed herein are merely illustrative of specific ways to make and use the invention and do not delimit the scope of the invention.

To facilitate the understanding of this invention, a number of terms are defined below. Terms defined herein have meanings as commonly understood by a person of ordinary skill in the areas relevant to the present invention. Terms such as “a”, “an” and “the” are not intended to refer to only a singular entity, but include the general class of which a specific example may be used for illustration. The terminology herein is used to describe specific embodiments of the invention, but their usage does not delimit the invention, except as outlined in the claims.

The ability to produce high surface area stable submicron and micron-sized protein particles would create new opportunities for oral, depot, pulmonary, and transdermal delivery applications (1-9). In pulmonary delivery, high surface area porous particles with aerodynamic diameters between 1-3 μm may be deposited more efficiently in the deep lung compared to dense particles with similar aerodynamic diameters (1, 8). In depot delivery, 300-500 nm submicron protein particles have been encapsulated uniformly into 10-50 μm diameter microspheres to achieve high protein loadings, while minimizing burst release (4, 6, 10, 11).

Solid protein particles, stabilized by cryoprotectants including sugars, are often less susceptible to destabilization during storage (1, 12-17) relative to proteins in solution. However, the formation of stable submicron protein particles with surface areas exceeding 10 m²/g (4, 18, 19) is highly challenging, as the removal of water exposes protein molecules to large interfacial areas. Adsorption of protein at gas-liquid and ice-liquid interfaces often results in unfolding and aggregation (1, 18-22). In lyophilization, the most common process for producing stable protein particles, particle growth during slow cooling (˜1 K/min) limits the particle diameter to a minimum of a few microns with surface areas less than 1 m²/g (21). The same limitation is true when drop freezing small aliquots (˜20-50 μL) of protein solution into liquid nitrogen (23), freezing thick (>500 μm) films on a cooled shelf (24), and plunge freezing ultra-thin walled PCR tubes filled with protein solution into liquid nitrogen (23). In these techniques, the protein solution was cooled at rates between 1 to 10 K/s (23, 24). Although the dried particles may be milled to form submicron particles, yields can be limited, size distributions are often broad, and the mechanical stress can lead to denaturation (1, 21). Submicron protein particles may be precipitated from aqueous solution by a variety of processes including spray-drying (11, 21, 22, 25), supercritical CO₂-assisted aerosolization and bubble drying (scCO₂A-BD) (26), spray freeze-drying (SFD) (1, 18, 19, 21), and spray freezing into liquids (SFL).

As used herein, “bioavailability” is a term meaning the degree to which a drug becomes available to the target tissue after being administered to the body. Poor bioavailability is a significant problem encountered in the development of pharmaceutical compositions, particularly those containing an active ingredient that is not highly soluble in water. In certain embodiments, the proteins may be water soluble, poorly soluble, not highly soluble or not soluble. The skilled artisan will recognize that various methodologies may be used to increase the solubility of proteins, e.g., use of different solvents, excipients, carriers, formation of fusion proteins, targeted manipulation of the amino acid sequence, glycosylation, lipidation, degradation, combination with one or more salts and the addition of various salts.

As used herein, the term “effective ingredient” refers to a compound or compounds, whether in pure or partially purified form (e.g., extracts) that has an known effect on target. For example, pharmaceutical agents are effective ingredients for their known target, e.g., penicillin is an effective ingredient or agent against susceptible bacteria. Another example of an effective ingredient is an insecticide that has a known insect target. The present invention may be used to manufacture and delivery effective ingredients against targets in a manner that will enhance its delivery, as specifically described hereinbelow.

As used herein, “pharmaceutically acceptable carrier” includes any and all solvents, dispersion media, coatings, antibacterial and antifungal agents, isotonic and absorption delaying agents. The use of such media and agents for pharmaceutical active substances is well known in the art. Except insofar as any conventional media or agent is incompatible with the active ingredient, its use in the therapeutic compositions is contemplated. Supplementary active ingredients can also be incorporated into the compositions.

In certain embodiments, pharmaceutical compositions may comprise, for example, at least about 0.1% of an active compound. In other embodiments, the an active compound may comprise between about 2% to about 75% of the weight of the unit, or between about 25% to about 60%, for example, and any range derivable therein. In other non-limiting examples, a dose may also comprise from about 1 microgram/kg/body weight, about 5 microgram/kg/body weight, about 10 microgram/kg/body weight, about 50 microgram/kg/body weight, about 100 microgram/kg/body weight, about 200 microgram/kg/body weight, about 350 microgram/kg/body weight, about 500 microgram/kg/body weight, about 1 milligram/kg/body weight, about 5 milligram/kg/body weight, about 10 milligram/kg/body weight, about 50 milligram/kg/body weight, about 100 milligram/kg/body weight, about 200 milligram/kg/body weight, about 350 milligram/kg/body weight, about 500 milligram/kg/body weight, to about 1000 mg/kg/body weight or more per administration, and any range derivable therein. In non-limiting examples of a derivable range from the numbers listed herein, a range of about 5 mg/kg/body weight to about 100 mg/kg/body weight, about 5 microgram/kg/body weight to about 500 milligram/kg/body weight, etc., can be administered, based on the numbers described above.

Particle formation technologies may be classified as either mechanical micronization processes or solution-based phase separation processes. Mechanical micronization methods include milling techniques such as that cited in U.S. Pat. No. 5,145,684. However, friction generated during these milling processes may lead to either thermal or mechanical degradation of the active pharmaceutical ingredient. Spray drying, another common method used to micronize drug substances, requires extremely high temperatures, on the order of 150° C., to remove the solvent from the drug following atomization. The elevated temperatures may accelerate degradation of the active ingredient.

Non-limiting examples of effective ingredients are pharmaceuticals, pharmaceutical agents, peptides, nucleic acids, proteins, antibiotics, gene therapy agents, catalysts, adsorbents, pigments, coatings, personal care products, abrasives, particles for sensors, metals, alloys, ceramics, membrane materials, nutritional substances, anti-cancer agents, as well as, chemicals used in the agriculture industries such as fertilizers, pesticides and herbicides. It will be appreciated that this list is not exhaustive and is for demonstrative purposes only. It will be further appreciated that it is possible for one compound to be included in more than one class of effective ingredients, for example, peptides and pharmaceuticals.

Examples of effective ingredients that are pharmaceutical agents include, but are not limited to, antibiotics, analgesics, anticonvulsants; antidiabetic agents, antifungal agents, antineoplastic agents, antiparkinsonian agents, antirheumatic agents, appetite suppressants, biological response modifiers, cardiovascular agents, central nervous system stimulants, contraceptive agents, diagnostic agents, dopamine receptor agonists, erectile dysfunction agents, fertility agents, gastrointestinal agents, hormones, immunomodulators, antihypercalcemia agents, mast cell stabilizers, muscle relaxants, nutritional agents, ophthalmic agents, osteoporosis agents, psychotherapeutic agents, parasympathomimetic agents, parasympatholytic agents, respiratory agents, sedative hypnotic agents, skin and mucous membrane agents, smoking cessation agents, steroids, sympatholytic agents, urinary tract agents, uterine relaxants, vaginal agents, vasodilator, anti-hypertensive, hyperthyroids, anti-hyperthyroids, anti-asthmatics and vertigo agents. Further examples of effective ingredients include a cardiovascular drug, respiratory drug, sympathomimetic drug, cholinomimetic drug, adrenergic or adrenergic neuron blocking drug, antidepressant, antihypertensive agent, anti-inflammatory, antianxiety agent, immunosuppressive agents, antimigraine agents, sedatives/hypnotic, antianginal agents, antipsychotic agents, antimanic agents, antiarrhythmic, antiarthritic agent, antigout agents, anticoagulant, thrombolytic agents, antifibrinolytic agents, hemorheologic agents, antiplatelet agents, anticonvulsant, antihistamine/antipruritic, agent useful for calcium regulation, antiviral agents, anti-infective, bronchodialator, hormone, hypoglycemic agent, hypolipidemic agent, protein, nucleic acid, agent useful for erythropoiesis stimulation, antiulcer/antireflux agent, antinauseant/antiemetic, oil-soluble vitamin, mitotane, visadine, halonitrosourea, anthrocycline or ellipticine.

The pharmaceutical effective ingredients may be used in a variety of application modalities, including oral delivery as tablets, capsules or suspensions; pulmonary and nasal delivery; topical delivery as emulsions, ointments or creams; and parenteral delivery as suspensions, microemulsions or depot. The resulting powder can be redispersed at any convenient time into a suitable aqueous medium such as saline, buffered saline, water, buffered aqueous media, solutions of amino acids, solutions of vitamins, solutions of carbohydrates, or the like, as well as combinations of any two or more thereof, to obtain a suspension that can be administered to mammals.

The solution agent used in the solution can be an aqueous such as water, one or more organic solvents, or a combination thereof. When used, the organic solvents can be water soluble or non-water soluble. Suitable organic solvents include but are not limited to ethanol, methanol, tetrahydrofuran, acetonitrile, acetone, tert-butyl alcohol, dimethyl sulfoxide, N,N-dimethyl formamide, diethyl ether, methylene chloride, ethyl acetate, isopropyl acetate, butyl acetate, propyl acetate, toluene, hexanes, heptane, pentane, and combinations thereof.

The excipients and adjuvants that may be used in the present invention, while potentially having some activity in their own right, for example, antioxidants, are generally defined for this application as compounds that enhance the efficiency and/or efficacy of the effective ingredients. It is also possible to have more than one effective ingredient in a given solution, so that the particles formed contain more than one effective ingredient.

As stated, excipients and adjuvants may be used to enhance the efficacy and efficiency of the effective ingredients. Non-limiting examples of compounds that can be included in the solutions that are to be spray frozen in accordance with the present invention include: cryoprotectants, lyoprotectants, surfactants, fillers, stabilizers, polymers, protease inhibitors, antioxidants and absorption enhancers. The excipients may be chosen to modify the intended function of the effective ingredient by improving flow, or bio-availability, or to control or delay the release of the effective ingredient. Specific nonlimiting examples include: sucrose, trehaolose, Span 80, Tween 80, Brij 35, Brij 98, Pluronic, sucroester 7, sucroester 11, sucroester 15, sodium lauryl sulfate, oleic acid, laureth-9, laureth-8, lauric acid, vitamin E TPGS, Gelucire 50/13, Gelucire 53/10, Labrafil, dipalmitoyl phosphadityl choline, glycolic acid and salts, deoxycholic acid and salts, sodium fusidate, cyclodextrins, polyethylene glycols, labrasol, polyvinyl alcohols, polyvinyl pyrrolidones and tyloxapol. Using the process of the present invention, the morphology of the effective ingredients can be modified, resulting in highly porous microparticles and nanoparticles.

In certain embodiments, the present invention demonstrates a novel method to produce stable submicron protein particles. The method is herein referred to as thin film freezing (TFF). FIG. 1 illustrates one embodiment of TFF. In TFF, liquid droplets typically fall from a given height and impact, spread, and freeze on a cooled solid substrate. In FIG. 1A, a droplet 10 falls from a given height, and impact a spinning surface 12 that has a temperature of 223 K. As the droplet spreads out, freezing front 14 is formed in advance of the unfrozen liquid 16 shown in FIG. 1B. Typically, the size of the completely frozen droplet 18 is about 12 mm in diameter, with a height approximently 216 μm. Recently, TFF was used to form high SSA powder (25-29 m²/g) of the poorly water soluble drug danazol (45). Liquid droplets (˜2-4 mm in diameter) were dispensed from a pipet above a cryogenically cooled metal surface (46, 47). Upon impact, the droplets spread out into thin films (˜100-400 μm) that froze on time scales of 70 to 1000 ms, which corresponds to a cooling rate of ˜10² K/s (42-44, 47-57). The cooling rates predicted with a 1-D heat transfer model were in agreement with laboratory measurements with an infrared (IR) camera (45). Since the cooling rates in TFF and SFL are comparable, TFF may be expected to be a desirable process for forming high surface area protein particles.

As will be apparent to those of skill in the art, the droplets may be delivered to the cold or freezing surface in a variety of manners and configurations. For example, to provide for high-throughput capabilities, the droplets may be delivered in parallel, in series, at the center, middle or periphery or a platen, platter, plate, roller, conveyor surface. The freezing or cold surface may be a roller, a belt, a solid surface, circular, cylindrical, conical, oval and the like that permit for the droplet to freeze. For a continuous process a belt, platen, plate or roller may be particularly useful. In operation, frozen droplets may form beads, strings, films or lines of frozen substrate and effective ingredient that are removed from the surface with a scraper, wire, ultrasound or other mechanical separator prior to the lyophilization process. Once the material is removed from the surface of the belt, platen, roller or plate the surface is free to receive additional material in a continuous process.

In certain embodiments, the present invention demonstrate submicron LDH and lysozyme particles (>10 m²/g) with 100% enzyme activity may be formed with TFF followed by lyophilization. The cooling rate was designed to be sufficiently fast to arrest particle growth, whereas the relatively small liquid-gas interfacial surface area helps prevent protein adsorption, unfolding and aggregation. The present invention presents dimensions of the thin films, stabilities (enzyme activity) of LDH powders after reconstitution, and morphologies of lysozyme particles determined by SEM and BET measurements of surface area. The present invention also gives cooling rates of the thin films determined by a 1-D heat transfer model and IR measurement. The cooling rates, particle morphologies and protein stabilities for the intermediate cooling rate processes TFF and SFL, relative to the ultra-rapid cooling process, SFD, and in the slow process, lyophilization were also compared. A protein nucleation and growth mechanism is presented to illustrate the particle morphologies in terms of the cooling rates. In TFF, the much smaller area of the gas-liquid interface of the falling droplet and spread film relative to the atomized droplets in SFD is shown to result in significantly less protein adsorption, and consequently, minimal denaturation and aggregation. Furthermore, the intermediate cooling rate (˜10² K/s) is shown to be sufficient to arrest particle growth to give surface areas>30 m²/g.

Compared to SFD and SFL, TFF offers the advantage of simplification in the processing steps, in addition to improvement in the stability of the protein. TFF on a cold metal surface bypasses the need to maintain aseptic conditions of a liquid cryogen, for example liquid nitrogen, in the SFD and SFL processes (24). The cooling rate of the thin films in TFF may be controlled readily by varying the temperature of the metal surface. Also, the surface temperature of the film may be measured directly (45). For SFL and SFD, the complex geometry of the turbulent spray in the liquid nitrogen (LN₂) combined with the Leidenfrost effect can be somewhat difficult to control and monitor (36). In TFF, more concentrated and thus more viscous solutions may be processed, as the droplets do not need to be atomized. In TFF, collection of the frozen films leads to nearly 100% yields. However, in SFD process yields were only about 80% as the result of entrainment of uncaptured particles in the atomized aqueous stream, particles sticking to the sides of collection vessels, and inefficient separation of the cryogen from the 10-100 μm frozen particles (11, 21).

Materials. Lysozyme was purchased from Sigma and L-LDH from porcine heart suspended in a 3.2 M ammonium sulfate solution from Roche Applied Science. Trehalose, NADH and pyruvate were purchased from Sigma. The water was deionized by flowing distilled water through a series of 2×7 L mixed bed vessels (Water and Power Technologies) containing 60:40 anionic:cationic resin blends.

LDH Enzyme preparation and catalytic activity assay. The LDH enzyme preparation and catalytic activity assay used in the present invention is described in detail in a previous reference (32). The LDH in ammonium sulfate was dialyzed against 10 mM KPO4 buffer (pH 7.5) at 4° C. for 3 hours before use (58, 59). LDH activities were measured for the reaction of pyruvate and NADH into lactate and NAD+. Units of LDH activity (U) were calculated by measuring the decrease in absorbance of NADH at λ=340 nm every 15 seconds for 1 minute due to the conversion of NADH to NAD over time (U=Δμmol NADH/min) and then dividing by the mass (mg) of the LDH protein in solution to determine specific activity (U/mg). The stability of the LDH formulation in 30 mg/mL trehalose was measured over time. The LDH specific activity remained stable for an hour and then began to decrease. All results were performed in the time period where the LDH specific activity had not decayed. During this time period, the specific activity was defined as 100%.

Example of the Thin Film Freezing (TFF) procedure. Aqueous protein solutions of LDH or lysozyme were passed at a flow rate of 4 mL/min either through a 17 gauge (1.1 mm ID, 1.5 mm OD) stainless steel syringe needle producing 3.6 mm diameter droplets or through 3.9 mm ID, 6.4 mm OD stainless steel tubing producing 5.6 mm diameter droplets. The droplets fell from a height of 10 cm above a rotating stainless steel drum 17 cm long and 12 cm in diameter. The stainless steel drum was hollow with 0.7 cm thick walls and was filled with dry ice or liquid nitrogen to maintain drum surface temperatures of 223 K or 133 K, respectively. Before each run, the surface temperature of the drum was verified with a DiGi-Sense® Type K thermometer using a 45° angle surface probe thermocouple attachment (Eutech Instruments). The drum rotated at approximately 12 rpm and was powered by a Heidolph RZR2041 mechanical overhead stirrer (ESSLAB) connected to a speed reducer. On impact the droplets deformed into thin films (FIG. 1) and froze. The frozen thin films were removed from the drum by a stainless steel blade mounted along the rotating drum surface. The frozen thin films then fell 5 cm into a 400 mL Pyrex® beaker filled with liquid nitrogen. For lysozyme, the frozen thin films in the 400 mL Pyrex® beakers were transferred directly to a −80° C. freezer to evaporate excess liquid nitrogen. For LDH, the frozen thin films were transferred from the 400 mL Pyrex® beakers into 50 mL polypropylene tubes (Part No. UP2255, United Laboratory Plastics) 2 cm in diameter and 16 cm in height using a spatula pre-cooled in liquid nitrogen.

Infrared Imaging of Cooling Thin Films. An InSb focal plane array (FPA) camera (Phoenix digital acquisition system (DAS camera, Indigo Systems) was positioned to acquire infrared images from above the cooling thin film on a flat plate. The FPA camera detected 3-5 μm radiation, and the images were acquired at 100 frames per second (10 ms/image). The dimensions of each frame were 256 pixels by 256 pixels (15 mm×15 mm). The image spatial resolution was approximately 40 μm per pixel. Average intensity values were calculated using MATLAB® version 6 (20×20 pixel square within the center of the droplet) and plotted versus time to determine the time for the center of the thin film to reach thermal equilibrium with the plate.

Drying and shelf loading. A Virtis Advantage Lyophilizer (The Virtis Company, Inc.) was used to dry the frozen slurries. The 400 mL beakers containing frozen slurries of lysozyme and the 50 mL polypropylene tubes containing the frozen slurries of LDH were covered with a single layer Kim-wipe. Primary drying was carried out at −40° C. for 36 hrs at 300 mTorr and secondary drying at 25° C. for 24 hrs at 100 mTorr. A 12 hour linear ramp of the shelf temperature from −40° C. to +25° C. was used at 100 mTorr.

LDH reconstitution and concentration assay. Dried LDH powders were reconstituted with 1 mL of DI water and the enzyme assay was performed immediately. After all protein samples had been analyzed for enzymatic activity, the protein concentration was measured with the BCA (bicinchoninic acid) protein analysis kit (Sigma Chemical Company). Once protein concentrations were determined, the specific activity from each measurement could be calculated. The activity of each LDH sample was normalized by the specific activity of the control measured immediately before the freezing process.

Transfer and storage of dried powders. After the lyophilization cycle was complete, the lyophilizer was purged with nitrogen upon releasing the vacuum to reduce the exposure time of the protein powders to water vapor in the ambient air before transfer. The samples were then rapidly transferred to a dry box held at 14% RH, and the powders were transferred to 20 mL scintillation vials. The vials were then covered with 24 mm Teflon® Faced Silicone septa (Wheaton) which were held in place by open-top screw cap lids. Vials were purged with dry nitrogen for 2 minutes via a needle through the septa and an additional needle for the gas effluent.

Surface area measurement. Surface areas of dried powders were measured with a Quantachrome Nova 2000 (Quantachrome Corporation) BET apparatus. Dried powders were transferred to the glass BET sample cells in a dry box. Samples were then degassed under vacuum for a minimum of 12 hours. The Brunauer, Emmett, and Teller (BET) equation (60) was used to fit adsorption data of nitrogen at 77 K over a relative pressure range of 0.05-0.30. The samples were measured two times.

Residual moisture content. Aliquots of methanol were dispensed through the septum of the scintillation vials to form a suspension concentration of 10-100 mg/mL. Vials were then placed in a bath sonicator (Mettler Electronics) for 5 minutes at maximum power to insure complete suspension of the powder. Moisture content was measured for a 200 μL aliquot with an Aquatest 8 Karl-Fischer Titrator (Photovolt Instruments). The moisture values were corrected with a 200 μL methanol blank control. All samples had a moisture content between 6-8% (w/w) after drying, comparable to values of 2-7% (w/w) for BSA prepared by SFD (18).

Particle size analysis. The size distribution of dried powders was measured by multiangle laser light scattering with a Malvern Mastersizer-S (Malvern Instruments). A mass of 30-100 mg of powder was suspended in 10 mL of acetonitrile and the suspension was then sonicated on ice for 1 minute using a Branson Sonifier 450 (Branson Ultrasonics Corporation) with a 102 converter and tip operated in pulse mode at 35 W. Typical obscuration values ranged from 11% to 13%. Aliquots of the sonicated suspension were then dispensed into a 500 mL acetonitrile bath for analysis.

Scanning electron microscopy (SEM). SEM images were collected on a Hitachi Model S-4500 scanning electron microscope (Hitachi Ltd). The samples were prepared in a dry-box. Aluminum stages fitted with double adhesive carbon conducting tape were gently dipped into sample vials until covered by powder. Stages were then placed in septum capped vials and purged with nitrogen for transfer. To minimize the time samples were exposed to atmospheric moisture the stages were rapidly transferred to a Pelco Model 3 sputter-coater. A conductive gold layer was applied and the samples were then quickly transferred to the SEM. Total exposure to the atmosphere was less than 1 minute.

Table 1 (below) shows the characterization of thin films formed from deionized water droplets as a function of surface temperature and droplet diameter.

TABLE 1 Thin Film from Thin Film from 3.6 mm Drop^(b) 5.6 mm Drop^(c) SFD^(a) SFL^(a) 223 K^(d) 133 K^(d) 223 K^(d) 133 K^(d) Droplet or Thin 10 100 12000 10000 23000 19000 Film Disk Diameter (μm) Film Thickness — — 216 311 221 324 (μm) Droplet or Thin 6000 600 46 32 45 31 Film Surface Area to Volume (cm⁻¹) ^(a)Values taken from Engstrom et al. (36) ^(b)Surface Area to Volume of 3.6 mm droplet is 17 cm⁻¹ ^(c)Surface Area to Volume of 5.6 mm droplet is 11 cm⁻¹ ^(d)Temperatures of stainless steel plate

The droplets spread on the cold metal surface and formed a cylindrical thin disk. The disk diameter decreased with a decrease in surface temperature from 223 K to 133 K and increased with an increase in falling droplet radius. Since the frozen thin films were cylindrical disks, the thicknesses of the thin films were calculated from the known volume of the liquid droplet and the measured disk diameter. The volumes of the falling droplets were determined by counting the number of droplets required to occupy 1 mL in a graduated cylinder. The average thin film thickness for the 223 K and 133 K surfaces were 220 μm and 320 μm, respectively. The corresponding surface area/volume ratios for the top surfaces of the cylinders are also shown in Table 1. The film thicknesses were essentially independent of the falling droplet diameter. For aqueous samples containing concentrations of lysozyme between 5 and 50 mg/mL or trehalose at 30 mg/mL, the droplet volumes, disk diameters, and thus film thicknesses did not change relative to pure water. The surface area/volume ratios for the 3.6 mm and 5.6 mm falling droplets in TFF were 17 cm⁻¹ and 11 cm⁻¹, respectively. As shown in Table 1, upon impact, the falling droplets spread into thin films with final surface area/volume ratios between 31 and 46 cm⁻¹. In a previous reference (36) of SFD and SFL, the corresponding surface area/volume ratios were 6000 and 600 cm⁻¹, respectively. Relative to these values, the much smaller surface area/volume ratio for TFF may be expected to lower the degree of protein destabilization from exposure to the gas-liquid interface.

The thin films were further characterized by determining the cooling rates from infrared measurements. The IR camera outputs intensity values with white indicating a high intensity and black a low intensity in relation to the amount of radiant energy E (energy density per unit time per unit wavelength) emitted from the droplet (45, 61). The radiant energy E is related to the temperature of the object according to Planck's law as equation (1)

E(λ,T)=(2πhc ²)/{λ⁵[exp(hc/λkT)−1]}  Equation (1)

where λ is the wavelength, c is the speed of light, k is the Boltzmann constant, h is Planck's constant and T is the temperature in Kelvin (61). Therefore, the intensity output of the IR camera is related directly to the temperature.

For the thin film on the 223 K surface shown in FIG. 2A, the diameter of the film was 12 mm and the edge was uniform and smooth. As cooling progressed, a cooling front moved radially inward from the edge of the film toward the center. The center of the film reached thermal equilibrium in 1.6 s shown in FIG. 2A and FIG. 3. For the thin film on the 133 K surface demonstrated in FIG. 2B, the diameter was 10 mm and dark jagged “fingers” were observed at the edge, indicating the coldest domains. The cooling front moved radially inward from the edge to the center at first. Next, the center turned black, and an annular region between the center and the outer jagged edge remained gray. The cooling front then reversed direction by moving from the center toward the edge of the film. FIG. 3 shows the center of the film reached thermal equilibrium a little more slowly, in about 3 s, relative to 223 K. In each case at the center of the film, a plateau was observed and then an abrupt final decay to thermal equilibrium.

The LDH activities for an aqueous formulation of 0.25 mg/mL LDH with 30 mg/mL trehalose frozen by lyophilization, SFL (32), and TFF were extremely high and not significantly different (p<0.05) according to a Student's t test shown in Table 2. Table 2 shows activities for 0.25 mg/mL LDH, 30 mg/mL trehalose formulations frozen by various techniques in pH 7.5, 10 mM KPO₄ buffer in replicates of 3.

TABLE 2 % Activity Freezing Process 223 K 133 K Thin Film (3.6 mm drop) 100 ± 3.9  104 ± 12.0 Thin Film (5.6 mm drop) 97 ± 9.5 100 ± 8.4  SFL^(a,d) 98 ± 5.3 SFD-130 μm^(a) 85 ± 8.2 SFD-40 μm^(a,e) 74 ± 6.7 SFD-10 μm^(a,d) 80 ± 5.4 Falling Droplet (3.6 mm)^(c) 98 ± 2.1 Spray into Air (10 μm)^(a,b,c) 85 ± 7.7 Lyophilization 99 ± 2.1 ^(a)Values taken from Engstrom et al. (32) ^(b)100 mg/mL trehalose used in LDH formulation ^(c)The droplets were not frozen in these two controls ^(d)Replicate of 4 ^(e)Replicate of 5

Compared to the SFD process for three droplet sizes, the LDH activities for each TFF condition were significantly higher (p<0.05). The very high LDH activities were maintained in the TFF process throughout the serial stresses of droplet falling and spreading, freezing, drying, and reconstitution.

Given the high enzyme activities for LDH particles formed by TFF, the other key goal was to demonstrate particle morphologies with submicron particle sizes and large particle surface areas. Table 3 demonstrates specific surface area measurements and particle size distributions for lysozyme powders formed by thin film freezing, SFL, and SFD.

TABLE 3 Lysozyme Concentration SSA (m²/g) Size (μm) Freeze Process (mg/mL) 223 K^(a) 133 K^(a) 223 K^(a) 133 K^(a) Thin Film (3.6 mm 5 73 ± 0.8 45 ± 0.4 0.050-1.0 (88%) 0.050-1.0 (81%) drop)   1.0-10 (12%)   1.0-12 (19%) Thin Film (5.6 mm 5 — — 0.050-1.0 (92%) 0.050-1.0 (84%) drop)   1.0-12 (8%)   1.0-10 (16%) Thin Film (3.6 mm 50 31 ± 0.1 55 ± 0.4 0.050-1.0 (66%) 0.050-1.0 (62%) drop)   1.0-30 (34%)   1.0-30 (38%) SFL^(b) 5 114 ± 11 0.050-1.0 (85%)   2.0-10 (15%) SFL^(b) 50 34 ± 2 0.050-1.0 (48%)   4.0-12 (52%) SFD-10 μm^(b) 50 126 ± 5  0.050-1.0 (74%)   1.0-10 (26%) Lyophilization 5  4.4 ± 0.2 0.05-1.0 (7%)   4.8-120 (93%) ^(a)Temperatures of stainless steel plate ^(b)Values taken from Engstrom et al. (36)

In the case of LDH, the ratio of LDH:trehalose was 1:120 by mass. As discussed previously (32, 36), the particle surface area for trehalose decreased upon exposure to atmospheric moisture which lowers the Tg sharply. (This limitation may be overcome in the future with the use of lyostoppers to seal the vials from moisture.) Thus, we chose lysozyme as a model protein to investigate powder morphology instead of LDH:trehalose. Lysozyme samples obtained and transfered at room temperature had moisture contents between 6-8% as determined by Karl Fischer titration. For moisture contents between 7-8% by weight, the Tg remained high, between 50-60° C. (62). Therefore the loss in lysozyme SSA during transfer may be expected to be negligible. For most cases, the SSA values were similar ranging between 30 and 55 m²/g. For 5 mg/mL lysozyme, the thinner films at 223 K produced a significantly higher SSA of 73 m²/g relative to the films at 133 K. In a previous reference (36), 5 and 50 mg/mL lysozyme solutions processed by SFL had measured powder SSAs of 114 m²/g and 34 m²/g, respectively, similar to the values produced by TFF (36). Although the SSA of 126 m²/g for SFD was about 2 fold larger than for TFF, the enzyme activity was much smaller, as shown in Table 2.

As shown in Table 3, the volume percentage of submicron particles, determined by laser light scattering, after sonication of the 5 mg/mL lysozyme formulation prepared by TFF at 223 K, ranged from 88 to 92%. The similarity in these two values was expected since the nearly identical thin film thicknesses would be expected to produce similar cooling rates. These values were similar to those for the SFL powders (36). For TFF, the protein powders were friable and could be broken up readily into submicron particles with minimal sonication. As shown in FIG. 4, the D(v,50) was 300 nm. In contrast, the same 5 mg/mL lysozyme formulation prepared by lyophilization had a very low fraction of 7% submicron particles shown in FIG. 4 and Table 3. As the lysozyme feed concentration was raised to 50 mg/mL the submicron fraction decreased to 66 and 62% on the 223 K and 133 K surfaces, respectively. The corresponding value for SFL was lower (48%), whereas for SFD it was higher (74%) (36). For the SFD powders, the D(v,50) was approximately 300 nm (36). A second peak with micron-sized particles was present for the 50 mg/mL lysozyme solution prepared by SFL and TFF as shown in Table 3. However, 50 mg/mL is an unusually high protein concentration and TFF would ordinarily be applied to concentrations on the order of 5 mg/mL, where the second larger peak is not present as shown in FIG. 4.

Selected SEM images from the results in Table 3 are shown in FIGS. 5 and 6. For 5 mg/mL lysozyme, fine 50 nm primary particles were produced by TFF at 223 K, demonstrated in FIG. 5A, comparable to those produced by SFL (36) in FIG. 5C. At 133 K, larger 50-100 nm diameter particles were mixed with rods 50-100 nm in diameter and more than 500 nm long as seen in FIG. 5B. The larger particles sizes shown in FIG. 5B compared to FIG. 5A are consistent with the slightly lower content of submicron particles measured by light scattering listed in Table 3.

For highly concentrated 50 mg/mL lysozyme solutions and a surface temperature of 223 K, large sheets were observed with features between 1 and 2 μm as shown in FIG. 6A. Similar features were observed for SFL (36). In contrast, a fine web with 100 nm features were produced by SFD (36) seen in FIG. 6C, which is consistent with the smaller particle sizes measured by light scattering in Table 3. The larger features observed in the TFF and SFL processes for 50 mg/mL versus 5 mg/mL solutions are consistent with the particle size distributions measured by light scattering. The similarity of the particle morphologies for the powders prepared by the SFL and TFF processes at both the 5 and 50 mg/mL concentrations are also examined in terms of cooling rates.

Modeling the cooling rate of thin films. Droplet spreading to form thin films of liquid metal and water droplets has been described in term of the Weber number, (inertial to interfacial forces) where is the impact velocity, is the droplet diameter, and is the droplet interfacial tension in air. For We >30 immediately before impacting the cooled solid substrate (42, 48-50, 56, 63) the droplets deformed into cylindrical thin films before freezing. For the low We<1 regime, impacting droplets froze as spherical domes with minimal droplet spreading (49, 64). For the falling liquid droplets, γ(air-water)=72 mN/m and V=(2gH)^(1/2) (65) where the falling height, H, of the droplet was 10 cm, resulting in V=1.4 m/s. The observed formation of thin cylindrical disks was consistent with this We of 97, but when H was reduced to less than 1 cm (We=9.8) the impacting water droplets froze as spherical domes that were only 4 mm in diameter.

Previously, it was shown with IR imaging studies of thin films formed with acetonitrile and t-butanol that droplet spreading occurred within the first 10 ms interval indicating that the droplet spreading time was much less than the freezing time (45). The same behavior was observed in FIG. 2 for water. The prediction of the cooling rate of the film with a simplified analytical heat transfer model was in good agreement with laboratory produced IR data (45). Herein, this approach is extended to thin film freezing of water droplets.

Briefly, the model assumes that the droplet spreads to form a cylindrical film on a much shorter time scale than heat transfer. Since the height (thickness) of the thin film is on the order of 200-400 μm, relative to a much larger diameter of 10-12 mm, radial heat transfer is neglected. The thermal diffusivity, α=k/ρ*C_(p), where k is the thermal conductivity, ρ is the density, and C_(p) is the heat capacity, is treated as constant over the entire temperature range. For the case of freezing water the thermal diffusivities of water and ice are averaged. One-dimensional heat transfer for a finite slab with an insulating boundary condition on the top surface of the thin film (air) and a constant temperature boundary condition on the bottom is described by equation (2)(66):

$\begin{matrix} {{T\left( {x,t} \right)} = {T_{p} + {\frac{2}{L}{\sum\limits_{n = 0}^{\infty}{e^{{- {\alpha {({{2n} + 1})}}^{2}}\pi^{2}{t/4}L^{2}}\cos \frac{\left( {{2n} + 1} \right)\pi \; x}{2L}\left\{ {\frac{2{L\left( {- 1} \right)}^{n + 1}T_{p}}{\left( {{2n} + 1} \right)\pi} + {\int_{0}^{L}{T_{i}\frac{{\cos \left( {{2n} + 1} \right)}\pi \; x^{\prime}}{2L}{dx}^{\prime}}}} \right\}}}}}} & {{Equation}\mspace{14mu} (2)} \end{matrix}$

where x is the distance from the top of the spread droplet, T is the temperature in the film, T_(p) is the plate temperature in contact with the bottom thin film surface, and L is the film thickness.

The calculated temperature profiles from equation (2) are shown in FIG. 7 and the calculated cooling rates and times are shown in Table 4 where calculated cooling rates, cooling times, and exposure time to the gas-liquid interface for SFD, SFL, and TFF are listed. The droplet dimensions are given in Table 1.

TABLE 4 Thin Film from 3.6 mm Thin Film from Drop 3.6 mm Drop SFD^(a) SFL^(a) 223 K 133 K Cooling Rate (K/s) 3.8 × 10⁶ 7.2 × 10³ 3.9 × 10² 2.0 × 10² Cooling Time (ms) 0.033 17 2.0 × 10² 6.2 × 10² Droplet Gas-Liquid 10-1000 2 ~1000 ~1000 Exposure Time (ms) ^(a)Values taken from Engstrom et al. (36)

The cooling time was defined as the time for the temperature of the top surface of the film, T(0,t), to decrease from room temperature (25° C.) to a value 5% greater than that of the metal surface. The cooling rate (K/s) was then determined by dividing the temperature difference at the top of the film by the cooling time. As shown in FIG. 7A and Table 4, the predicted time to cool the top surface of the 220 μm thick thin film on the 223 K surface is 2.0×10² ms (cooling rate of 3.9×10² K/s). The calculated cooling rate is an order of magnitude less than for SFL (7.2×10³ K/s) and 4 orders of magnitude less than for SFD (3.8×10⁶ K/s). The much smaller cooling rates in TFF versus SFD may be explained by a 100 fold smaller surface area/volume ratio and a film thickness on the order of 20-30 times larger than the droplet radius in SFD.

The particle morphologies shown in FIG. 5 and particle SSAs in Table 3 were similar for freezing on the 223 K and 133 K surfaces, as a consequence of the rapid cooling in each case.

The testing cooling times to reach thermal equilibrium were longer by a factor of 3-4 compared to the modeled cooling times as demonstrated in Table 4. This difference is small compared to difference in orders of magnitude relative to other processes such as SFL and lyophilization. The difference may be the result of uncertainty in the calibration of the temperature measurement, differences in definitions of the final temperature for the model and IR camera, and the release of the heat of fusion of water which was not factored into the model. For extremely rapid cooling rates of water, the water may form a glass with limited crystallization (67). As shown by data and calculation, a cooling rate of 10⁶ K/s is necessary to vitrify water (67-70). The 10² K/s cooling rate observed in TFF indicates that the latent heat of fusion may have been significant.

Nucleation and Growth Mechanisms versus Cooling Rate. To place the TFF results in perspective, it is instructive to consider the boundary conditions of extremely rapid vitrification/freezing in SFD and slow freezing in lyophilization. Previously, the morphologies of lysozyme powders prepared by SFL and SFD were shown to be similar for dilute 5 mg/mL lysozyme solutions. The SSAs were >100 m²/g for 50-100 nm spherical primary particles, despite a cooling rate of 10³ K/s for SFL versus 10⁶ K/s for SFD, as shown in Table 4 (36).

The freezing mechanism involves many simultaneous changes in the properties of the unfrozen solution. As the water freezes, it changes concentrations, pH, ionic strength, viscosity, diffusion coefficients, collisions between nucleated particles and geometric size and shape of the unfrozen solution. The growth rate of the protein particles depends upon all of these factors, such that it would be challenging to develop a model for the final particle size. The thin liquid channels between the frozen water domains reduce the number of collisions between protein (sugar) particles and thus inhibit growth by coagulation, as shown in FIG. 8. Furthermore, the viscosity of the thin channels increases rapidly to arrest particle growth and the channel fully freezes. Furthermore, the sugar in the water raises the viscosity over that of pure water. For the case of slow cooling in lyophilization, the very low degree of supercooling creates relatively few nucleated ice domains compared to the rapid cooling processes, leaving thick channels of liquid solution between these domains. For a cooling rate of 1 K/min, as for the case of slowly cooling a 5 mg/mL solution in a −20° C. freezer, the lyophilized particle sizes were on the order of 30-100 μm. In these thick channels, the protein particles have sufficient time to aggregate and grow forming large particles before the channels are fully frozen. Although it is theoretically possible to mitigate this particle growth partially by reducing the protein solution concentration significantly below 1 mg/mL, such low protein concentrations can lead to excessive lyophilization requirements (21).

In SFD, the present inventors found that exposure of the protein to the gas-liquid interface has a larger effect on protein stability than to the ice-liquid or glassy water-liquid interface (19, 31, 32). It is unclear whether ice-liquid versus glassy water-liquid interfaces have different effects on protein stabilities (19, 20, 71). As described by previous references (68, 69), cooling rates on the order of 10⁶ K/s are needed to vitrify water, but the cooling rate necessary for vitrification can be lowered in the presence of sugar in solution (67, 70). For the slower cooling rates observed in TFF (10² K/s) relative to SFD, it is likely that ice particle domains instead of vitrified water domains are formed. The LDH activities were on the order of 100% for TFF. Thus, the present invention does not suggest that the ice-liquid interface has a detrimental effect on protein stability.

For the 5 mg/mL lysozyme formulation at 223 K, the SSA was quite large, although modestly smaller than for SFD, and the particle sizes after sonication were similar to those of both SFL and SFD as seen in Table 3. The lower cooling rate in TFF (10² K/s) compared to SFD (10⁶ K/s) and SFL (10³ K/s) was still sufficient to produce rapid nucleation and to prevent significant particle growth during freezing. However, for TFF, the size of the unfrozen channels was sufficiently thin and the increase in the viscosity of the unfrozen solution sufficiently fast to achieve similar particle sizes and morphologies as for the moderately faster process, SFL and much faster process, SFD. Thus, the extremely rapidly cooling rates in SFD were much faster than necessary to form submicron protein particles. A similar conclusion was reached in the comparison of SFL and SFD (32).

For 50 mg/mL highly concentrated solutions the larger volume fraction of vitrified solute domains in the unfrozen water channels lead to a greater collision frequency and increased particle growth (36). As observed previously (36), the slower cooling rate in SFL compared to SFD leads to greater particle growth before the large unfrozen liquid channels vitrify, leading to larger protein particles and lower powder SSAs (36). As shown in Table 3, the SSAs were similar for TFF and SFL. For these highly concentrated solutions, the larger particles formed in TFF (and SFL) versus SFD results from more time for growth in the thicker unfrozen channels. This limitation is typically not encountered in rapid freezing processes, as most previous studies examined much lower concentrations on the order of 5 mg/mL.

Minimization of gas-liquid interface in TFF process. The LDH stabilities were essentially 100% after TFF indicating that none of the steps, droplet falling, spreading and freezing, and drying caused a measurable loss in enzyme activity. From previous calculations (32) it was shown that the exposure of the atomized droplets to the gas-liquid interface was an order of magnitude less in the SFL process (600 cm⁻¹) relative to SFD (6000 cm⁻¹) (19). This larger exposure to the gas-liquid interface resulted in lower LDH activities in SFD (32). In TFF the surface area/volume ratio of the gas-liquid interface of TFF (46 cm⁻¹) was 2 orders of magnitude lower than in SFD, leading to far less protein adsorption and aggregation. As shown in FIG. 9, the intermediate cooling rates in TFF and SFL offer a means to produce high surface area submicron particles as opposed to lyophilization, with smaller amounts of protein adsorption at gas-liquid interfaces compared to SFD resulting in higher protein stability.

Minimizing gas-liquid interface can improve protein stability by limiting the amount of protein that can adsorb to the interface. For surface active radiolabeled proteins, the surface excess concentration, Γ, (72, 73) at full saturation for β-casein, lysozyme, and BSA were 2.6, 3.0, and 3.3 mg/m², respectively (33, 72, 73). For LDH, we assumed a similar value of approximately 3 mg/m2. For the top surface of a 12 mm diameter film, where the surface area is 1.13×10−4 m², the total adsorbed protein at equilibrium would be 3.4×10−4 mg. For a starting 3.6 mm liquid droplet containing 0.25 mg/mL LDH, the total protein is 6.2×10⁻³ mg. Therefore, if all of the protein reached the interface and was denatured, the maximum decrease in protein activity would be 5.5%. The exposure of 1 s may not lead to full equilibrium adsorption. Furthermore, the increase in viscosity as a function of height and time with freezing will arrest diffusion of protein to the air-water interface. For ˜10 μm diameter droplets in SFD, it was determined that 25-30% of the total LDH in the droplet adsorbs to the gas-liquid interface in only 0.4 ms (22). Denaturation of part of the adsorbed protein is consistent with the significant decreases in protein activity observed in the SFD process in Table 2.

The TFF process was utilized to produce 300 nm lysozyme particles with surface areas on the order of 31-73 m²/g and 100% LDH activities. Despite a cooling rate of ˜10² K/s in TFF, the particle sizes and surface areas were similar to those observed in the widely reported process, spray freeze drying SFD, where cooling rates reach 10⁶ K/s. In TFF, the thin liquid channels between the ice domains were sufficiently thin and freezing rates of the thin channels sufficiently fast to achieve the similar particle morphologies. Therefore, the extremely rapid cooling rate in the SFD process was not necessary to form the desired submicron protein particles. Although LDH was exposed to the gas-liquid interface of the thin film for a maximum of ˜1 s in TFF, the surface area/volume of 45 cm⁻¹ was sufficiently small that adsorption produced negligible aggregation and denaturation. Even if this gas-liquid interface became saturated with protein, followed by irreversible denaturation, the maximum activity loss for a 0.25 mg/mL LDH formulation would be 5%. For SFD with a droplet size of 10 μm, the maximum loss could reach 25% in just 0.4 ms from diffusion to the interface and adsorption (22), consistent with the significant decrease in enzyme activity (80%). In SFD, losses in protein stability have been observed in several previous studies (1, 11, 18, 19, 21). Although LDH stabilities are high in conventional lyophilization, cooling rates are on the order of 1 K/min resulting in large 30 to 100 μm sized particles (21). Thus, the intermediate cooling rate regime for TFF (and likewise for SFL), relative to SFD and lyophilization, offers a promising route to form stable submicron protein particles of interest in pulmonary and parenteral delivery applications.

Example 1

The solutions frozen using the TFF process has a final concentration of 5 mg Lysozyme/mL solvent where the solvent was a water/ethanol mixture at different concentration. The feed solution was then passed through a 17 gauge needle at a flow rate of 4 mL/min falling from a height of 10 cm onto a rotating stainless steel drum maintained at a temperature of 223 K where the droplets were allowed to spread into disks and freeze. The frozen disks were then lyophilized using the standard lyophilization procedure described above. The resulting particle sizes (FIG. 11) were measured using the Malvern Mastersizer as described previously.

Example 2

Solutions in varying initial concentrations of lysozyme in water were frozen as described above and then lyophilized to produce microparticles. The frozen particles were frozen on the rotating drum and then scrapped off into small vial for individual dosages. The particle sizes produced were measured using the Malvern Mastersizer as described above (FIG. 12).

FIGS. 13A to 13D compare the morphologies of TFF lysozyme prepared in glass vial versus TFF on a drum. Briefly, thin film freezing was performed directly in a vial that was cooled by submerging it partially in a liquid cryogenic fluid, or a fluid composed of dry ice and solvent. The feed was lysozyme at 5 mg/mL. The water in the frozen material was then removed by lyophilization of the vial. The product remained in the vial. A sample was removed from the vial and analyzed by scanning electron microscopy. The morphology was similar to a sample prepared directly on a metal drum. The advantage of this technique is that TFF may be performed directly in a glass vial to make particle with submicron features. The final dosage form may then be formulated by adding excipients to the particles in the vial.

TFF was performed using a feed of 150 mg/mL lysozyme in D.I. water. Once these samples were lyophilized, they were redispersed in acetonitrile to break the particles apart. The acetonitrile wa then removed by TFF. The final particles after lyophilization were redispered in benzyl benzoate to form a stable suspension (FIG. 14).

The present invention demonstrates a simple, efficient and robust process for freezing either small (<1 mL) quantities of protein solution or commercial quantities, that can produce stable submicron protein particles.

It is contemplated that any embodiment discussed in this specification can be implemented with respect to any method, kit, reagent, or composition of the invention, and vice versa. Furthermore, compositions of the invention can be used to achieve methods of the invention.

It will be understood that particular embodiments described herein are shown by way of illustration and not as limitations of the invention. The principal features of this invention can be employed in various embodiments without departing from the scope of the invention. Those skilled in the art will recognize, or be able to ascertain using no more than routine experimentation, numerous equivalents to the specific procedures described herein. Such equivalents are considered to be within the scope of this invention and are covered by the claims.

All publications and patent applications mentioned in the specification are indicative of the level of skill of those skilled in the art to which this invention pertains. All publications and patent applications are herein incorporated by reference to the same extent as if each individual publication or patent application was specifically and individually indicated to be incorporated by reference.

The use of the word “a” or “an” when used in conjunction with the term “comprising” in the claims and/or the specification may mean “one,” but it is also consistent with the meaning of “one or more,” “at least one,” and “one or more than one.” The use of the term “or” in the claims is used to mean “and/or” unless explicitly indicated to refer to alternatives only or the alternatives are mutually exclusive, although the disclosure supports a definition that refers to only alternatives and “and/or.” Throughout this application, the term “about” is used to indicate that a value includes the inherent variation of error for the device, the method being employed to determine the value, or the variation that exists among the study subjects.

As used in this specification and claim(s), the words “comprising” (and any form of comprising, such as “comprise” and “comprises”), “having” (and any form of having, such as “have” and “has”), “including” (and any form of including, such as “includes” and “include”) or “containing” (and any form of containing, such as “contains” and “contain”) are inclusive or open-ended and do not exclude additional, unrecited elements or method steps.

The term “or combinations thereof” as used herein refers to all permutations and combinations of the listed items preceding the term. For example, “A, B, C, or combinations thereof” is intended to include at least one of: A, B, C, AB, AC, BC, or ABC, and if order is important in a particular context, also BA, CA, CB, CBA, BCA, ACB, BAC, or CAB. Continuing with this example, expressly included are combinations that contain repeats of one or more item or term, such as BB, AAA, MB, BBC, AAABCCCC, CBBAAA, CABABB, and so forth. The skilled artisan will understand that typically there is no limit on the number of items or terms in any combination, unless otherwise apparent from the context.

All of the compositions and/or methods disclosed and claimed herein can be made and executed without undue experimentation in light of the present disclosure. While the compositions and methods of this invention have been described in terms of preferred embodiments, it will be apparent to those of skill in the art that variations may be applied to the compositions and/or methods and in the steps or in the sequence of steps of the method described herein without departing from the concept, spirit and scope of the invention. All such similar substitutes and modifications apparent to those skilled in the art are deemed to be within the spirit, scope and concept of the invention as defined by the appended claims.

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1.-50. (canceled)
 51. A freezing surface comprising a frozen drug composition layered on the surface, the drug composition comprising a proteinaceous pharmaceutical agent wherein the layer has a thickness of less than 500 micrometers and a surface area to volume of from 25 to 500 cm⁻¹.
 52. The surface of claim 51, formed by a process comprising dissolving the agent in one or more solvents; spraying or dripping droplets of said dissolved pharmaceutical agent such that the pharmaceutical agent is exposed to a vapor-liquid interface of less than 500 cm⁻¹ area/volume; and contacting the droplets with a freezing surface that has a temperature differential of at least 30° C. between the droplets and the surface, wherein the surface freezes the droplets into a film with a thickness of less than 500 micrometers and a surface area to volume between 25 to 500 cm⁻¹, to thereby form the freezing surface comprising a frozen drug composition layered on the surface.
 53. The surface of claim 52, wherein the solvent is selected from the group consisting of ethanol, methanol, tetrahydrofuran, acetonitrile, acetone, tert-butyl alcohol, dimethyl sulfoxide, N,N-dimethyl formamide, diethyl ether, methylene chloride, ethyl acetate, isopropyl acetate, butyl acetate, propyl acetate, toluene, hexanes, heptane, pentane, and combinations thereof.
 54. The surface of claim 52, further comprising the step of removing the solvent from the frozen material to form micron or submicron sized particles.
 55. The surface of claim 52, wherein the droplets freeze upon contact with the surface in about 50, 75, 100, 125, 150, 175, 200, 250, 500, 1,000 and 2,000 milliseconds.
 56. The surface of claim 52, wherein the droplets freeze upon contact with the surface in 50, 150, or 500 milliseconds.
 57. The surface of claim 52, wherein the droplet has a diameter between 0.1 and 5 mm at room temperature.
 58. The method of claim 52, wherein the droplet has a diameter between 2 and 4 mm at room temperature.
 59. The surface of claim 51, wherein the solid surface is made of glass or metal.
 60. The surface of claim 51, wherein the solid surface is a roller, a platter, a plate, a platen surface, a conveyor surface, a flat surface, a circular surface, a cylindrical surface, a conical surface or an oval surface.
 61. The surface of claim 51 or 52, wherein solvent present has been removed and the drug composition is in the form of micron or submicron sized particles.
 62. The surface of claim 61, wherein the particles have a surface area per unit weight of 10, 15, 25, 50, 75, 100, 125, 150 or 200 m²/gram.
 63. The surface of claim 51, wherein the particle has less than 50% of the peptide or protein at the particle surface.
 64. The surface of claim 51, wherein the proteinaceous pharmaceutical is an enzyme.
 65. The surface of claim 51, wherein the proteinaceous pharmaceutical is a polypeptide.
 66. The surface of claim 51, wherein the proteinaceous pharmaceutical is water soluble. 